TY - JOUR
T1 - Multiscale modeling of diffuse damage and localized cracking in quasi-brittle materials under compression with a quadratic friction law
AU - Zhao, Lun Yang
AU - Ren, Lu
AU - Liu, Ling Hui
AU - Lai, Yuan Ming
AU - Niu, Fu Jun
AU - You, Tao
N1 - Publisher Copyright: © 2024 The Author(s)
PY - 2024/11/1
Y1 - 2024/11/1
N2 - The diffuse damage and localized cracking of quasi-brittle materials (i.e., rocks and concretes) under compression can be delineated by a matrix-microcrack system, wherein a solid matrix phase is weakened by a large number of randomly oriented and distributed microcracks, and the macroscopic cracking is formed by a progressive evolution of microcracks. Several homogenization-based multiscale models have been proposed to describe this matrix-microcrack system, but most of them are based on a linear friction law on the microcrack surface, rendering a linear strength criterion. In this paper, we propose a new quadratic friction law within the local multiscale friction-damage (LMFD) model to capture the plastic distortion due to frictional sliding along the rough microcrack surface. Following that, a macroscopic Ottosen-type nonlinear strength criterion is rationally derived with up-scaling friction-damage coupling analysis. An enhanced semi-implicit return mapping (ESRM) algorithm with a substepping scheme is then developed to integrate the complex nonlinear constitutive model. The performance of LMFD model is evaluated compared to a wide range of experimental data on plain concretes, and the robustness of ESRM algorithm is assessed through a series of numerical tests. Subsequently, to effectively describe the localized cracking process, a regularization scheme is proposed by combining the phase-field model with the established LMFD model, and the discretization independent crack localization is numerically verified.
AB - The diffuse damage and localized cracking of quasi-brittle materials (i.e., rocks and concretes) under compression can be delineated by a matrix-microcrack system, wherein a solid matrix phase is weakened by a large number of randomly oriented and distributed microcracks, and the macroscopic cracking is formed by a progressive evolution of microcracks. Several homogenization-based multiscale models have been proposed to describe this matrix-microcrack system, but most of them are based on a linear friction law on the microcrack surface, rendering a linear strength criterion. In this paper, we propose a new quadratic friction law within the local multiscale friction-damage (LMFD) model to capture the plastic distortion due to frictional sliding along the rough microcrack surface. Following that, a macroscopic Ottosen-type nonlinear strength criterion is rationally derived with up-scaling friction-damage coupling analysis. An enhanced semi-implicit return mapping (ESRM) algorithm with a substepping scheme is then developed to integrate the complex nonlinear constitutive model. The performance of LMFD model is evaluated compared to a wide range of experimental data on plain concretes, and the robustness of ESRM algorithm is assessed through a series of numerical tests. Subsequently, to effectively describe the localized cracking process, a regularization scheme is proposed by combining the phase-field model with the established LMFD model, and the discretization independent crack localization is numerically verified.
KW - Homogenization-based multiscale modeling
KW - Integration algorithm
KW - Phase-field model
KW - Quadratic friction law
KW - Quasi-brittle materials
UR - http://www.scopus.com/inward/record.url?scp=85202295966&partnerID=8YFLogxK
U2 - 10.1016/j.ijsolstr.2024.113038
DO - 10.1016/j.ijsolstr.2024.113038
M3 - Article
AN - SCOPUS:85202295966
SN - 0020-7683
VL - 304.2024
JO - International journal of solids and structures
JF - International journal of solids and structures
IS - 1 November
M1 - 113038
ER -